Understanding, Control, and Optimisation of Free Volume Mediated Transport in Technologically Important Materials. The understanding gained by this work will enable Australian scientists to outpace their competitors in rational materials design for transport of atoms and molecules in materials while reducing the costly trial and error stage of research. Specific examples studied and new materials investigated have important technological significance from use in flat panel TV screens, to solid ....Understanding, Control, and Optimisation of Free Volume Mediated Transport in Technologically Important Materials. The understanding gained by this work will enable Australian scientists to outpace their competitors in rational materials design for transport of atoms and molecules in materials while reducing the costly trial and error stage of research. Specific examples studied and new materials investigated have important technological significance from use in flat panel TV screens, to solid state electrolytes for application in a wide range of electrochemical devices. The understanding gained by this work can be applied to a wide range of important materials e.g. separation membranes, nanofilters and catalysts which help address a number of National Research Priorities.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100115
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
High-temperature probes for investigating phase transitions and reaction kinetics in thin films, nanostructured materials and biomaterials. This infrastructure for high temperature surface analysis and in-situ diagnostics as a function of temperature and gas environments will enhance Australia's capabilities in creating new materials for devices that will meet needs in medical, communications, environmental and security applications. The facility will enable researchers to understand and exploi ....High-temperature probes for investigating phase transitions and reaction kinetics in thin films, nanostructured materials and biomaterials. This infrastructure for high temperature surface analysis and in-situ diagnostics as a function of temperature and gas environments will enhance Australia's capabilities in creating new materials for devices that will meet needs in medical, communications, environmental and security applications. The facility will enable researchers to understand and exploit interfacial phenomena and to tailor processing-microstructure-composition correlations, so as to design new materials with the best performance possible. Probes with unique capabilities will measure surface morphology, optical properties, elemental composition and crystallographic phase.The facility will be the first in Australia to offer a comprehensive study of structure and properties at high temperature.Read moreRead less
Optimisation of the electrical and optical properties of ZnO nanowires for advanced nanodevice applications. It is widely accepted that nanowires and related structures will provide the key for the construction of future functional nano-devices with unprecedented performance. In this project we will develop robust protocols for the fabrication of ZnO nanowires in the lab which can be meet the needs of specific nanotechnology and nanodevice applications and once established these growth technique ....Optimisation of the electrical and optical properties of ZnO nanowires for advanced nanodevice applications. It is widely accepted that nanowires and related structures will provide the key for the construction of future functional nano-devices with unprecedented performance. In this project we will develop robust protocols for the fabrication of ZnO nanowires in the lab which can be meet the needs of specific nanotechnology and nanodevice applications and once established these growth techniques can reconfigured for industrial scale fabrication. Development of these nanowire growth techniques will enable Australia to be at the leading edge in the rapidly emerging field of nano-science and nano-technology.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989986
Funder
Australian Research Council
Funding Amount
$230,000.00
Summary
Hybrid Fourier Transform Dispersive Raman Micro-Spectrometer. This facility will be used in a wide range of existing and new research projects in government priority areas such as the development of new materials, frontier technologies for building and transforming existing industries, better understanding of diversity and functioning in mycorrhizal and other fungi in forest soils and plant roots and developing new characterisation methods for forensic investigations. The proposed equipment aims ....Hybrid Fourier Transform Dispersive Raman Micro-Spectrometer. This facility will be used in a wide range of existing and new research projects in government priority areas such as the development of new materials, frontier technologies for building and transforming existing industries, better understanding of diversity and functioning in mycorrhizal and other fungi in forest soils and plant roots and developing new characterisation methods for forensic investigations. The proposed equipment aims to provide outstanding opportunities for the training of research students, expanding research in the fields of materials, minerals, geological, environmental and forensic science enabling to maintain Australia's lead and competitiveness in cutting edge research and technology. Read moreRead less
Development of Low Cost, High Quality Nitrides for Solid-State Lighting and Other Power Saving Applications. The advent of high brightness, low cost, compact, low power white light-emitting diodes (LEDs) will revolutionise lighting as we currently know it. Incandescent light bulbs and fluorescent tubes are inefficient light sources and their replacement with high efficiency solid state LED lighting over the next 10 years will provide a 10% reduction in global greenhouse gas emissions. The develo ....Development of Low Cost, High Quality Nitrides for Solid-State Lighting and Other Power Saving Applications. The advent of high brightness, low cost, compact, low power white light-emitting diodes (LEDs) will revolutionise lighting as we currently know it. Incandescent light bulbs and fluorescent tubes are inefficient light sources and their replacement with high efficiency solid state LED lighting over the next 10 years will provide a 10% reduction in global greenhouse gas emissions. The development and enhancement of a recent Australian innovation for the fabrication of low cost high brightness LEDs will enable Australia to be at the frontier of this technology and to be a world leader in the next stage of its development.Read moreRead less
A Mechanistic Approach to the Compression Properties of Z-Pinned Composites. The proposed research is a fundamental investigation of the compressive mechanical properties and failure mechanisms of fibre reinforced polymer (FRP) composites reinforced with z-pins. These composites are a new material with strong potential applications in aerospace structures subject to high compressive loads, however their compressive properties are poorly understood. Using theoretical modelling, finite element an ....A Mechanistic Approach to the Compression Properties of Z-Pinned Composites. The proposed research is a fundamental investigation of the compressive mechanical properties and failure mechanisms of fibre reinforced polymer (FRP) composites reinforced with z-pins. These composites are a new material with strong potential applications in aerospace structures subject to high compressive loads, however their compressive properties are poorly understood. Using theoretical modelling, finite element analysis and experimentation, the research program will greatly enhance the fundamental understanding of the strengthening and failure mechanisms of z-pinned composites. A key outcome of the research will be design guidelines for optimising the pinning of composites for maximum structural performance in aerospace applications.Read moreRead less
Band gap engineering of novel (In,Ga)SbN epitaxial semiconductors for high-performance long-wavelength optoelectronic devices. This proposal is at the forefront of a number of important fields, and therefore the outcomes are expected to be of great interest to a broad spectrum of industry sectors, including national defence, health care, environment and manufacturing. This novel material system could create new high technologies for various infrared devices. The outcomes of this project will pos ....Band gap engineering of novel (In,Ga)SbN epitaxial semiconductors for high-performance long-wavelength optoelectronic devices. This proposal is at the forefront of a number of important fields, and therefore the outcomes are expected to be of great interest to a broad spectrum of industry sectors, including national defence, health care, environment and manufacturing. This novel material system could create new high technologies for various infrared devices. The outcomes of this project will position Australian researchers among the pioneering groups in this area and will be beneficial to several major technology-related fields: global warming and associated environmental monitoring, security systems, thermal-imaging systems for night vision, and healthcare with the emphasis on disease diagnosis and treatment.Read moreRead less
Crystalline Mesoporous Metal Oxides for Solid Oxide Fuel Cell Electrodes. Our crystalline mesoporous electrodes will help realise the full potentials of solid oxide fuel cells. Such advanced fuel cell technology will drastically increase the power generation efficiency, and reduce CO2 emissions from present power plants, thereby transforming Australian energy industry and improving our environment. The design and development of novel crystalline mesoporous materials that find widespread industri ....Crystalline Mesoporous Metal Oxides for Solid Oxide Fuel Cell Electrodes. Our crystalline mesoporous electrodes will help realise the full potentials of solid oxide fuel cells. Such advanced fuel cell technology will drastically increase the power generation efficiency, and reduce CO2 emissions from present power plants, thereby transforming Australian energy industry and improving our environment. The design and development of novel crystalline mesoporous materials that find widespread industrial applications will advance Australia's knowledge and skill base, and help Australia's high-tech industries to stay competitive, including the development of new high-tech industries in Australia.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160100569
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Ultra-Porous Devices by Synergistic Aerosol and Atomic Layer Depositions. The project aspires to develop a scalable low-cost approach for the synthesis and integration of ultra-porous films in nanodevices. The project intends to deposit atomic layers onto aerogel-like nanoparticle networks, self-assembled by thermophoresis of flame-made aerosols. This would increase the atomically-deposited layer mass by several hundred-fold per cycle and result in ultra-porous films with electrochemically activ ....Ultra-Porous Devices by Synergistic Aerosol and Atomic Layer Depositions. The project aspires to develop a scalable low-cost approach for the synthesis and integration of ultra-porous films in nanodevices. The project intends to deposit atomic layers onto aerogel-like nanoparticle networks, self-assembled by thermophoresis of flame-made aerosols. This would increase the atomically-deposited layer mass by several hundred-fold per cycle and result in ultra-porous films with electrochemically active surface areas. It is intended that the project will demonstrate the fabrication of solid–gas, solid–liquid and solid–solid nanointerfaces, which will be applicable to key emerging technologies such as wearable medical diagnostics.Read moreRead less
A novel approach to direct nanopatterning of silicon for advanced phase-changed devices. This project will exploit key research developments at ANU in the field of nanotechnology, specifically nanofabrication of entirely new devices. In particular, this work will be exploited by a new Australian high-tech company, WRiota, to produce novel silicon phase change devices. The instrumentation developments will be commercialized by a leading nanoindentation company and the materials and device-related ....A novel approach to direct nanopatterning of silicon for advanced phase-changed devices. This project will exploit key research developments at ANU in the field of nanotechnology, specifically nanofabrication of entirely new devices. In particular, this work will be exploited by a new Australian high-tech company, WRiota, to produce novel silicon phase change devices. The instrumentation developments will be commercialized by a leading nanoindentation company and the materials and device-related outcomes and IP will be retained and used by WRiota. This project will further provide valuable opportunities for a number of research students and ECRs to gain experience in both the industrial and academic worlds.Read moreRead less